More Activity at Yellowstone

Is it about to blow? Yellowstone supervolcano is hit by 878 earthquakes in just over TWO WEEKS – the most active it has been for five years

  • Strongest earthquake of 4.4 magnitude hit on Thursday 15 June 
  • This could be a warning sign of an impending eruption of the supervolcano
  • If it did erupt, it would be one thousand times as powerful as Mount St Helens

A swarm of nearly 900 earthquakes have hit Yellowstone National Park since 12 June, according to experts.

The park sits on one of the world’s most dangerous supervolcanoes and recent activity has raised fears the supervolcano is about to blow.

If it were to erupt, the Yellowstone volcano would be one thousand times as powerful as the 1980 Mount St Helens eruption, experts claim – although they say the risk is ‘low’.

A swarm of hundreds of earthquakes have hit Yellowstone National Park with up to 4.4 magnitude. The Grand Prismatic hot spring (pictured) is among the park's many hydrothermal features created by the supervolcano (stock image)

A swarm of hundreds of earthquakes have hit Yellowstone National Park with up to 4.4 magnitude. The Grand Prismatic hot spring (pictured) is among the park’s many hydrothermal features created by the supervolcano (stock image)

EARTHQUAKE SWARM

Researchers from the University of Utah’s Seismograph Stations (UUSS) have been monitoring the activity since it began last Monday, June 12.

A total of 878 quakes have been recorded over the past fortnight at Yellowstone.

Earthquake swarms are common in Yellowstone and, on average, comprise about 50 per cent of the total activity in the Yellowstone region.

Although the latest swarm is the largest since 2012, it is fewer than weekly counts during similar events in 2002, 2004, 2008 and 2010.

The tremors were recorded at depths from ground level to nine miles (14.5 km) below sea level.

Seismic activity could be a sign of an impending eruption of the supervolcano, although this is currently impossible to predict exactly.

A total of 878 quakes have been recorded over the past fortnight at Yellowstone.

When the earthquakes started on 12 June, the United States Geological Survey (USGS) said it was the highest number of earthquakes at the park within a single week in the past five years.

Researchers from the University of Utah’s Seismograph Stations (UUSS) have been monitoring the activity since it began on Monday, June 12.

The strongest quake of 4.4 magnitude hit on Thursday, June 15.

‘The swarm consists of one earthquake in the magnitude 4 range, 5 earthquakes in the magnitude 3 range, 68 earthquakes in the magnitude 2 range, 277 earthquakes in the magnitude 1 range, 508 earthquakes in the magnitude 0 range, and 19 earthquakes with magnitudes of less than zero’, the report said.

‘Earthquake swarms are common in Yellowstone and, on average, comprise about 50 per cent of the total seismicity in the Yellowstone region’.

‘UUSS will continue to monitor this swarm and will provide updates as necessary.’

UUSS said the quake was part of ‘an energetic sequence’ of earthquakes magnitude two and larger in the area.

A spokesman said: ‘The epicentre of the shock was located in Yellowstone National Park, eight miles north-northeast of the town of West Yellowstone.

‘The earthquake was felt in the towns of West Yellowstone and Gardiner, Montana, in Yellowstone National Park, and elsewhere in the surrounding region.’

Earthquake swarms are common in Yellowstone and, on average, comprise about 50 per cent of the total activity in the Yellowstone region.

Researchers from the University of Utah's Seismograph Stations (UUSS) have been monitoring the activity since it began last Monday, June 12. Pictured  is the he location of the earthquakes that are part of the swarm as  (red symbols)

Researchers from the University of Utah’s Seismograph Stations (UUSS) have been monitoring the activity since it began last Monday, June 12. Pictured  is the he location of the earthquakes that are part of the swarm as (red symbols)

Although the latest swarm is the largest since 2012, it is fewer than weekly counts during similar events in 2002, 2004, 2008 and 2010.

The tremors were recorded at depths from ground level to nine miles (14.5 km) below sea level.

Earthquake swarms are common in Yellowstone and, on average, comprise around 50 per cent of the total seismic activity in the Yellowstone region. Pictured - seismic data for the magnitude 4.4 quake which took place on Thursday, June 15

Earthquake swarms are common in Yellowstone and, on average, comprise around 50 per cent of the total seismic activity in the Yellowstone region. Pictured – seismic data for the magnitude 4.4 quake which took place on Thursday, June 15

The University of Utah is part of the Yellowstone Volcano Observatory (YVO), which provides long-term monitoring of volcanic and earthquake activity in the region.

YVO is one of the five United States Geological Survey volcano observatories that monitor volcanoes within the United States for science and public safety.

In a written statement, a spokesman for the team said: ‘Yellowstone hasn’t erupted for 70,000 years, so it’s going to take some impressive earthquakes and ground uplift to get things started.’

‘Besides intense earthquake swarms, we expect rapid and notable uplift around the caldera.

‘Finally, rising magma will cause explosions from the boiling-temperature geothermal reservoirs.

‘Even with explosions, earthquakes and notable ground uplift, the most likely volcanic eruptions would be the type that would have minimal effect outside the park itself.’

Yellowstone is the site of the largest and most diverse collection of natural thermal features in the world.

SCIENTISTS FIND A MASSIVE MAGMA CHAMBER UNDER YELLOWSTONE PARK

Previous research found a relatively small magma chamber, known as the upper-crustal magma reservoir, beneath the surface

Previous research found a relatively small magma chamber, known as the upper-crustal magma reservoir, beneath the surface

In the heart of Yellowstone National Park, a supervolcano releases around 45,000 metric tonnes of carbon dioxide each day.

But the magma chamber lying directly beneath its surface is not considered large enough to produce such levels, so researchers have been searching for an alternative source for years.

In April 2015, by tracking seismic waves, geophysicists discovered a huge secondary chamber deeper underground that’s so large its partly-molten rock could fill the Grand Canyon 11 times over.

Previous research found a relatively small magma chamber, known as the upper-crustal magma reservoir, directly beneath the surface in 2013 that measures 2,500 cubic miles (10,420 cubic km).

To discover the latest chamber, Hsin-Hua Huang from the University of Utah and his colleagues tracked seismic waves from almost 5,000 earthquakes.

This USGS graphic shows how a 'super eruption' of the molten lava under Yellowstone National Park would spread ash across the United States

This USGS graphic shows how a ‘super eruption’ of the molten lava under Yellowstone National Park would spread ash across the United States

These readings combined data from the University of Utah Seismograph Stations, which collected shallow readings from nearby quakes in Utah, Idaho, the Teton Range and Yellowstone, and from the Earthscope array, which revealed deeper readings from temblors from more further afield.

Each of these quakes created waves that echoed around the supervolcano.

The movement and structure of these waves could then be used to map the earth beneath.

The researchers said in their paper: ‘The Yellowstone magmatic system from the mantle plume to the upper crust’, published in the journal Science, that the reservoir contains around 98 per cent hot rock.

The remaining 2 per cent is molten rock and is too deep to directly cause an eruption, they added

Seismic activity could be a sign of an impending eruption of the supervolcano, although this is currently impossible to predict exactly.

While it has lain dormant for more than 70,000 years, scientists say that we can’t rule out the possibility eruption may some day take place, although they say the chances are extremely slim.

A magnitude 4.8 earthquake, which hit the park in 2014, was the most powerful to strike the area in nearly 30 years.

In 2013, a study into the super volcano found the underground magma chamber to be 2.5 times larger than previously thought, with the cavern spanning a 56 mile (90km) by 19 miles (30km) area and capable of holding tons of molten rock.

Experts say there is a one in 700,000 annual chance of a volcanic eruption at the site. Pictured is an artist's impression

Experts say there is a one in 700,000 annual chance of a volcanic eruption at the site. Pictured is an artist’s impression

Yellowstone National Park spans the midwestern US states of Wyoming, Idaho and Montana (pictured)

Yellowstone National Park spans the midwestern US states of Wyoming, Idaho and Montana (pictured)

The volcano a sits atop a huge reserve of molten rock that last erupted 640,000 years ago.

It is one of the largest active continental silicic volcanic fields in the world. Silicic is used to describe magma or igneous rock rich in silica.

The Grand Prismatic hot spring in Yellowstone National Park is among the park’s many hydrothermal features created by the Yellowstone supervolcano.

Experts say there is a one in 700,000 annual chance of a volcanic eruption at the site.

If the volcano were ever to erupt, observers say the outflow of lava, ash and smoke would likely devastate the United States and affect the entire world.

THE MASSIVE LAKE OF MOLTEN CARBON THE SIZE OF MEXICO FOUND UNDER YELLOWSTONE

 A huge well of molten carbon that would spell disaster for the planet if released was found under the Yellowstone in February.

Scientists using the world’s largest array of seismic sensors have mapped a deep-Earth area, covering 700,000 sq miles (1.8 million sq km).

This is around the size of Mexico, and researchers say it has the potential to cause untold environmental damage.

The discovery could change our understanding of how much carbon the Earth contains, suggesting it is much more than we previously believed.

A huge well of molten carbon that would spell disaster for the planet if released has been found under the US (stock image) 

A huge well of molten carbon that would spell disaster for the planet if released has been found under the US (stock image)

It would be impossible to drill far enough down to physically ‘see’ the Earth’s mantle, so a team of researchers used a massive group of sensors to paint a picture of it, using mathematical equations to interpret their results.

The study, conducted by geologists at Royal Holloway University in London, used a huge network of 583 seismic sensors that measure the Earth’s vibrations, to create a picture of the area’s deep sub surface.

Known as the upper mantle, this section of the Earth’s interior is known for by its high temperatures where solid carbonates melt, creating distinctive seismic patterns.

Scientists uncovered a huge reservoir of molten carbon situated under the Western US, 217 miles (350km) beneath the Earth's surface

Scientists uncovered a huge reservoir of molten carbon situated under the Western US, 217 miles (350km) beneath the Earth’s surface

What they found was a vast buried deposit of molten carbon, which produces carbon dioxide and other gases, situated under the Western US, 217 miles (350km) beneath the Earth’s surface.

If just a fraction of the carbon found by the Royal Holloway team were released into the atmosphere, it could have grave implications for the planet.

Just one per cent of the CO2 stored would be equivalent to burning 2.3 trillion barrels of oil.

If a substantial amount was released all at once, it could bring about an environmental disaster on the scale of nuclear warfare.

(Check out link for video at bottom.)

The Growing RIft in Africa

Why Is Africa Ripping Apart? Seismic Scan May Tell

Charles Q. Choi, OurAmazingPlanet Contributor
Date: 19 June 2013
Lakes along the Great African Rift Valley
 This radar image highlights portions of three of the lakes located in the Western Rift of the Great Rift Valley, a geological fault system of Southwest Asia and East Africa: Lake Edward (top), Lake Kivu (middle) and Lake Tanganyika (bottom).
CREDIT: ESA

Arrays of sensors stretching across more than 1,500 miles in Africa are now probing the giant crack in the Earth located there — a fissure linked with human evolution — to discover why and how continents get ripped apart.

Over the course of millions of years, Earth’s continents break up as they are slowly torn apart by the planet’s tectonic forces. All the ocean basins on the Earth started as continental rifts, such as the Rio Grande rift in North America and Asia’s Baikal rift in Siberia.

The giant rift in Eastern Africa was born when Arabia and Africa began pulling away from each other about 26 million to 29 million years ago. Although this rift has grown less than 1 inch (2.54 centimeters) per year, the dramatic results include the formation and ongoing spread of the Red Sea, as well as the East African Rift Valley, the landscape that might have been home to the first humans.

“Yet, in spite of numerous geophysical and geological studies, we still do not know much about the processes that tear open continents and form continental rifts,” said researcher Stephen Gao, a seismologist at the Missouri University of Science and Technology in Rolla, Mo. This is partly because such research has mostly focused on mature segments of these chasms, as opposed to ones that are still in development, he explained.

Seismic SAFARI

Geodynamic models suggest that below mature rifts, a region called the asthenosphere is upwelling. The asthenosphere is the hotter, weaker, upper part of the mantle that lies below the lithosphere, the planet’s outer, rigid shell. So far, there are two contenders for what might cause this upwelling: anomalies deeper in the mantle or thinning of the lithosphere due to distant stresses.

To help find out which of the two different rifting models is correct, the Seismic Arrays for African Rift Initiation (SAFARI) project installed 50 seismic stations across Africa in the summer of 2012, each spaced about 17 to 50 miles (28 to 80 kilometers) apart.

“One of the techniques that we will use to image the Earth beneath the SAFARI stations is called seismic tomography, which is in principle similar to the X-ray CAT-scan technique used in hospitals,” Gao told LiveScience’s OurAmazingPlanet. “The only differences are that our sources of the ‘rays’ are earthquakes and man-made explosions, and the receivers are the seismic stations such as the 50 SAFARI stations.”

Altogether, these arrays encompass a length of about 1,550 miles (2,500 km) and are located in four countries — Botswana, Malawi, Mozambique and Zambia.

“I think the project has a positive impact on local communities,” Gao said. “Some of our 50 SAFARI seismic stations are on local schools, and the teachers and students were excited and were proud about the fact that their school was selected for a high-tech scientific instrument. We believe that this project showed some kids that the outside world is different and even fascinating.”

The arrays will image the areas under the Okavango, Luangwa and Malawi rifts, the southwest and southernmost segments of the East African Rift system. These so-called incipient rifts are not yet mature and could thus shed light on why and how rifting occurs.

“This is the first large-scale project to image the structure and deformation beneath an incipient rift,” Gao said. “The Okavango rift in Botswana is as young as a few tens-of-thousand years, while most other rifts such as the Rio Grande and Baikal rifts are as old as 35 million years.”

Upwelling or thinning?

If thermal or dynamic anomalies deep in the mantle are responsible for rifting, then upwelling from the asthenosphere should already be occurring beneath these incipient rifts. In contrast, if thinning of the lithosphere is the cause of rifting, then any levels of upwelling should be insignificant because the lithosphere should not have thinned adequately for major upwelling to occur yet.

A magnitude-5.6 earthquake in November near the northern end of the Indian Ocean’s mid-ocean ridge sent out seismic waves that were more than 1 second slower than predicted. This supports the idea that the mantle layer beneath Southern Africa is hotter than normal, perhaps due to a jet of magma known as a mantle plume that geologists have proposed exists beneath this area.

To image the structures beneath these rifts and pin down what the rifting mechanism in Eastern Africa is, researchers need data from more than just one event. The seismic arrays will be deployed for 24 months, and each station will sample the Earth for seismic waves 50 times per second.

“We are anxious to see if there are melted rocks in the mantle beneath the rifts, if there is convective mantle flow that is driving the rifting process, and how much the crust has been thinned in different portions of the rifts,” Gao said. “But this cannot be done until next summer, when all the data recorded by SAFARI are processed.”

The scientists detailed their findings to date in the June 11 issue of Eos, the online newspaper of the American Geophysical Union.

from:    http://www.livescience.com/37542-african-rift-valley-seismic-array.html

Magma Activity in Three Sisters Area in Oregon

Magma Causing Uplift in Oregon

Charles Q. Choi, OurAmazingPlanet Contributor
Date: 04 January 2012 Time: 11:22 AM ET
Three Sisters
The Three Sisters area — which contains five volcanoes — is only about 170 miles (274 km) from Mount St. Helens, which erupted in 1980. Both are part of the Cascades Range, a line of 27 volcanoes stretching from British Columbia in Canada to northern California. This perspective view was created by draping a simulated natural color ASTER image over digital topography from the U.S. Geological Survey National Elevation Dataset.
CREDIT: NASA/GSFC/MITI/ERSDAC/JAROS, and U.S./Japan ASTER Science Team

Volcanic activity is causing the earth to rise in Oregon, scientists have found.

Though whether such uplift is a sign of an imminent eruption remains uncertain.

As early as the summer of 1996, a 230-square-mile (600-square-kilometer) patch of ground in Oregon began to rise. The area lies just west of the South Sister Volcano, which with the North and Middle Sisters form the Three Sisters volcanoes, the most prominent peaks in the central Oregon stretch of the Cascade Mountains.

Although this region has not seen an eruption in at least 1,200 years, the scattered hints of volcanic activity here have been a cause of concern, leading to continuous satellite-based monitoring. Now 14 years of data is revealing just how the Earth is changing there and the likely cause of the uplift — a reservoir of magma invading the crust 3-to-4 miles (5-to-7 km) underground.

Uplifting ground

The European Space Agency’s European Remote Sensing and Envisat radar satellites revealed that the terrain deformed in three distinct phases since this uplift began. From 1996 to 1998, the ground rose by 0.4 inches (1 cm) per year. Then, from 1998 to 2004, uplift grew to 1.2-to-1.6 inches (3-to-4 cm) annually. However, for the rest of the decade, uplift declined to only a few millimeters per year, for a total of 9.8 inches (25 cm) of uplift so far.

“The most important implication of our research is that the ground appears to still be uplifting,” said researcher Susan Riddick, a geodesist at the University of Oregon. “Previous researchers believed that the ground uplift, a result of the input of magma deep in the Earth’s crust, had stopped at around 2006. We found that the ground is still uplifting as of late 2010 and may still be uplifting, but at a slow rate.”

By analyzing precisely how the landscape was changing, the researchers suggest the magma pocket behind this uplift has a volume of 1.76-billion-to-2.47-billion cubic feet (50-million-to-70-million cubic meters), enough to fill 20,000-to-28,000 Olympic-size swimming pools.

Eruption monitoring

Since the ground is still rising, “magma may still be accumulating, and as a result, this area needs to be continually monitored to determine whether or not there will be an eruption,” Riddick told OurAmazingPlanet.

“If there were to be an eruption, it would probably not be from a pre-existing volcano that we can see because the uplifting ground area is several kilometers from historically active volcanoes,” Riddick added. “A new volcanic vent would likely form. Lava would be ejected from a vent and fall to the ground to create a cinder cone, which is a steep conical volcano made of lava fragments. We believe it would be a small eruption, because we calculated that only a relatively small amount of magma has accumulated in the earth’s crust so far.”

If the researchers are correct, ” if an eruption were to take place, it would produce a small cinder cone, then the eruption would be localized within the Three Sisters wilderness area and would not pose a great hazard to the public in neighboring towns,” Riddick said. “However, this can change if more magma accumulates at depth, which is why continual monitoring of this area is crucial.”

Riddick and her colleague David Schmidt detailed their findings online Dec. 17 in the journal Geochemistry, Geophysics, Geosystems.

from:    http://www.livescience.com/17727-magma-causing-oregon-uplift.html

 

More Activity at El Hierro

Signs of second eruption off coast of El Hierro
English.news.cn   2011-10-31 20:54:10

MADRID, Oct. 31 (Xinhua) — A second volcanic eruption off the coast of the island of El Hierro could be on the point of happening, scientists warned.

The warning came just over a week after the end of the first eruption, which forced a village on the island to be evacuated.

The offshore eruption began at a depth of over 100 meters below sea level on Oct. 10 off the southern coast of El Hierro, the smallest and most westerly of the Canary Islands, a group of islands off the western coast of Africa, which are governed by Spain.

It led to the creation of a stain caused by emissions of sulphur, pumice stone and magma which extended beyond El Hierro.

Although the first eruption died down and seismic activity began to fade, it has gained momentum again in recent days with El Hierro suffering over 120 earth tremors with the strongest reaching 3.9 on the Richter scale on Sunday.

In contrast to the first eruption, there are signs that a second eruption could happen off the northern coast of El Hierro.

Experts have met with government members of the Canary Islands to discuss the new developments. Although no new measures will be taken for the moment to evacuate the population from areas closest to a possible eruption site, the authorities will maintain their close observation of the area.

“What is happening in el Hierro has a lot of questions that still need answers. The movements have been changing their location and we need to continue studying the process to find conclusions,” explained volcanologist Nemesio Perez to Spain’s national broadcaster RTVE.

“What we do know is that there is activity with magma and this chapter has still not been closed,” he said.

 

from:    http://news.xinhuanet.com/english2010/world/2011-10/31/c_131222445.htm